*Daisuke Tsumune1, Tsubono Takaki1, Kazuhiro Misumi1, Michio Aoyama2
(1.Central Research Institute of Electric Power Industry, 2.Center for Research in Isotopes and Environmental Dynamics, University of Tsukuba)
Keywords:Fukushima Daiichi Nuclear Power Plant accident, Direct release, Caesium-137, Regional ocean model
In order to elucidate the actual state of marine contamination from the Fukushima Daiichi Nuclear Power Station (F1NPS) accident, a reproduction calculation was conducted using an oceanic dispersion model, primarily for 137Cs. The Regional Ocean Model System (ROMS) with a horizontal resolution of 1 km was driven by realistic driving forces from meteorological reanalysis data. Data assimilation (nudging) was also employed using results from the ocean reanalysis data (JCOMP2) to reproduce the effects of the Kuroshio and meso-scale eddies. By using realistic driving forces, it was possible to reproduce the large temporal changes in 137Cs concentrations in the early stages of the F1NPS accident. The oceanic dispersion model was particularly useful for estimating the source term of direct releases from the F1NPS site. The released 137Cs diluted significantly in a north-south direction due to the influence of coastal currents. In addition, the 137Cs activity concentration distribution was complicated by the strong influence of meso-scale eddies. The temporal variation of the 137Cs activity concentration distribution was large, although the annual mean distribution had smaller spatial variability. The reproducibility was verified by comparing the annual mean calculated values with the annual mean observed values. The influence of atmospheric deposition was predominant for 137Cs activity concentration in the ocean immediately after the accident, and the influence of direct release was predominant for about a year from March 26, 2011. After that, the direct release effect continued to dominate in the vicinity of the F1NPS site, and the reproduced annual mean calculation results agreed with the annual mean observations. Predictive simulations of APLS treated water have also been conducted using this verified model. However, the slightly remote coastal area was found to be affected by recirculation of 137Cs deposited on the North Pacific scale. In order to understand the effects of recirculation, it is necessary to understand the distribution of atmospheric deposition on the North Pacific scale, although this is still unresolved due to the paucity of observational data. A combined approach of an atmospheric transport model and an oceanic dispersion model is needed. In order to estimate the impact of river discharge, it is necessary to understand the complex process of settlement, resuspension, and re-leaching of 137Cs supplied in particle form from rivers into the ocean. Quantitative discussion of the effects of atmospheric deposition and river discharge on the current underestimation.